Transcriptional And Cell Cycle Control Of Erythropoiesis By E2F4
Funder
National Health and Medical Research Council
Funding Amount
$447,750.00
Summary
The balance in the number of cells in our body is a carefully regulated process which, when disturbed, can lead to a number of life-threatening diseases such as cancer. Through genetic studies in the mouse, we previously identified E2F4 as a protein that is required for the correct number of red blood cells in the body. Lack of E2F4 results in anaemia in the mouse embryo. We have studied these mice as a model to understand how cell production in the body can be controlled. In recent studies, we ....The balance in the number of cells in our body is a carefully regulated process which, when disturbed, can lead to a number of life-threatening diseases such as cancer. Through genetic studies in the mouse, we previously identified E2F4 as a protein that is required for the correct number of red blood cells in the body. Lack of E2F4 results in anaemia in the mouse embryo. We have studied these mice as a model to understand how cell production in the body can be controlled. In recent studies, we have identified proliferation defects and in particular cell division cycle defects as the major cause for the decreased production of red blood cells in the embryo. In addition, we have utilised gene microarray technology to survey which genes change in the absence of E2F4 by comparing gene expression profiles in normal and E2F4 deficient mice. These studies have identified a large number of genes that could be molecular targets for E2F4 and whose defective expression could be ultimately responsible for the anaemia of these mice. Importantly, our data suggests a completely novel function for E2F4 in controlling the switching on of genes required for cell division. In this proposal, we describe approaches to characterise how E2F4 controls the cell division cycle to identify the exact process(es) it may control such as DNA replication or separation of chromosomes into daughter cells. We will also test our hypothesis for a novel role for E2F4 in being able to switch on genes in nucleated red blood cell. Finally, we describe gene microarray experiments and a new promoter microarray approach to close in on the molecules directly required for the E2F4 control of red blood cell production. Because defects in the E2F family of proteins or the proteins that regulate them, the retinoblastoma, pRB family, have been implicated as central for cancer development, these studies will have broad implications for therapeutic targeting of this pathway in cancer.Read moreRead less
The Role Of The PRB/E2F Pathway In Erythropoiesis And Cell Cycle Control
Funder
National Health and Medical Research Council
Funding Amount
$272,036.00
Summary
Circulating blood contains two major types of cells. Red blood cells supply the oxygen required by all cells in our body to survive and white blood cells protect our body from invasion by foreign organisms. The balance in the number of these cells in our blood is a carefully regulated process which, when disturbed, can lead to a number of life-threatening blood diseases. Uncontrolled overgrowth of blood cells results in a particular type of cancer known as leukaemia. In contrast, when there is a ....Circulating blood contains two major types of cells. Red blood cells supply the oxygen required by all cells in our body to survive and white blood cells protect our body from invasion by foreign organisms. The balance in the number of these cells in our blood is a carefully regulated process which, when disturbed, can lead to a number of life-threatening blood diseases. Uncontrolled overgrowth of blood cells results in a particular type of cancer known as leukaemia. In contrast, when there is an insufficient number of red blood cells, not enough oxygen reaches cells from the brain and other vital organs and results in a condition known as anaemia. We have genetically engineered a mouse that lack the protein known as E2F4 and is unable to produce enough red blood cells and suffers from anaemia. This protein, E2F4, controls genes essential for the decision of cells to start or stop growing and multiplying. The E2F4-deficient mice therefore provide a new and powerful model to understand the mechanism by which disturbance of red blood cell numbers can lead to diseases such as leukaemia and other diseases of the blood. Identification of the genes controlled by E2F4 may provide new targets for the development of therapeutic drugs to combat these diseases.Read moreRead less